Abstract: An imaging system (10) and associated method for detection of protein contamination on a surgical instrument (100) that has been treated with a fluorescing stain, wherein fluorophors in the stain are capable of emitting light of an emitted type when both excited by light of an excitation type and in contact with a protein are provided. The system comprises a light tight chamber (14) for receiving the instrument (100). Inside the chamber (14) are both visible light sources (20) and excitation light sources (22) for respectively illuminating the chamber with visible and excitation type light. A digital camera (30) is able to capture a first image of the instrument (100) as illuminated by the visible light, and a second image, of patterns of fluorescence produced by the fluorophors in the stain corresponding to protein contamination. The first and second images are combined to produce a composite image of the instrument (100) highlighting the areas of protein contamination.

Abstract: An imaging system 10 for automatically capturing an image of a faint pattern of light emitted by a specimen comprises: an electronic image capture device 12, such as a camera having a CCD sensor; a light-tight enclosure 24 having within a platform 32 for mounting a light-emitting specimen 30 thereon within the field of view of the image capture device 12; and a computer 50, connected to at least the image capture device 12. The computer 50 is adapted to: estimate a maximum signal level that can be expected from the specimen 30 and calculate, based on said estimated maximum signal level, a peak signal level estimate (psle); calculate an exposure time on the basis of the psle and a desired resolution for a captured image; and capture an image for the calculated exposure time. The desired resolution may a user-selected choice, balancing a need for quality of final image against the time required to capture it. An associated method is also disclosed.

Abstract: A tunable color LED module comprises at least two sub-modules, each comprising an LED (104), a wavelength converting element (WCE) (201, 112, 203) and a reflector cup. The total light emitted by the module comprises light generated from each LED and WCE and the module is configured to emit a total light having a predefined color chromaticity when activation properties of the LEDs are managed appropriately. The total light may have a broad white emission spectrum (106). The module combines the benefits of a low cost with uniform chromaticity properties in the far field, and offers long and controlled lifetime at the same time as flexibility and intelligence of tunable color chromaticity, Color Rendering Index (CRI) and intensity, either at manufacture or in an end user lighting application. A controlled LED module system comprises a control system for the managing activation properties of the LEDs in the sub-modules. Also described is a method of manufacture.

Abstract: An imaging system (10) and associated method for detection of protein contamination on a surgical instrument (100) that has been treated with a fluorescing stain, wherein fluorophors in the stain are capable of emitting light of an emitted type when both excited by light of an excitation type and in contact with a protein are provided. The system comprises a light tight chamber (14) for receiving the instrument (100). Inside the chamber (14) are both visible light sources (20) and excitation light sources (22) for respectively illuminating the chamber with visible and excitation type light. A digital camera (30) is able to capture a first image of the instrument (100) as illuminated by the visible light, and a second image, of patterns of fluorescence produced by the fluorophors in the stain corresponding to protein contamination. The first and second images are combined to produce a composite image of the instrument (100) highlighting the areas of protein contamination.

Abstract: A system and an associated method of imaging microbial colonies in high fidelity and in colour. Differently coloured light sources are turned on and off in sequence and for each illumination colour an image is captured by a monochrome camera. The resultant respective monochrome images are combined into a composite colour image of the microbial colonies.

Abstract: A method of creating an image 4 obtained from say a camera 1 to obtain a substantially linear representation of the brightness of the image includes, for each of a set of pixels (x, y) in a two dimensional array, calculating, in a computer 3, an estimate of the true image intensity (ixy) as a weighted average of n samples of the apparent image intensity (vn,xy). This is calculated as: i ^ xy = ? n ? ? ( w n , xy ? ( v n , xy - C KT n ) ) ? n ? w n , xy = 1 K ? ? n ? ? ( w n , xy ? ( v n , xy - C T n ) ) ? n ? w n , xy where vn,xy is the apparent intensity measured, Tn is the exposure time, K is the gain of the system, C is an offset and wn,xy is a weighting factor which is defined to maximize the signal to noise ratio and discard insignificant, that is saturated or near zero, values.

Abstract: A system is provided for creating a larger montage image 8 of an object from a series of smaller source images 7 of different views of an object through, say, a microscope which forms an imaging means for providing images of an object. A data storage means such a framestore board 4 in a computer 5 stores data representative of the montage image of the object. Data representative of a first and subsequent source images is included in that representative of the montage image, in order to increase the data stored representative of the montage image.